Litcius/Paper detail

Ductility deterioration induced by L21 phase in ferritic alloy through Ti addition

Xu Chen, Shaowen Peng, Ye Liu, Song Bai, Lin Zhang, Shuang He, Oleg I. Gorbatov, Xuanhui Qu

2023Journal of Materials Research and Technology16 citationsDOIOpen Access PDF

Abstract

Ductility deterioration induced by L21-Ni2AlTi precipitates in the aged ferritic alloys was examined systematically by using a combination of scanning transmission electron microscope (STEM), mechanical tests and first-principles thermodynamic calculations. The experimental studies revealed that the strength and hardness of the aged Fe–10Cr–5Ni–1Al–1Ti ferritic alloy containing B2–NiAl and L21-Ni2AlTi precipitates were higher than that of the aged Fe–10Cr–5Ni–1Al ferritic alloy containing NiAl precipitates, whereas the elongation-to-failure decreased dramatically from 9.3% to 0.3% indicating an obvious ductility deterioration due to the formation of L21-Ni2AlTi precipitates. This was also confirmed by the observation of fracture transition mode from dimpled failure to cleavage failure. The first-principles calculations, concerning the precipitate/matrix interface, were carried out to provide a theoretical analysis for the ductile–brittle transition by means of empirical ductility criteria ratios G/B and (C12–C44)/B as well as cleavage energy. The cleavage energy results indicated an intrinsic brittleness of the L21-Ni2AlTi phase and the L21-Ni2AlTi/BCC-Fe interface. Our analysis revealed that the intrinsic brittleness of L21-Ni2AlTi phase and L21-Ni2AlTi/BCC-Fe interface plays a vital role in determining the deformation behavior of the aged Fe–10Cr–5Ni–1Al–1Ti alloy.

Topics & Concepts

Materials scienceDuctility (Earth science)AlloyBrittlenessCleavage (geology)MetallurgyComposite materialFracture (geology)CreepMicrostructure and Mechanical Properties of SteelsFusion materials and technologiesHigh Temperature Alloys and Creep